Comfort Comes With Green Building
Mechanical Systems Play a Critical Role in Making a House Comfortable.
Wider Comfort Ranges Save Energy
For any given individual, there is a range of temperatures and humidity levels within which the person feels comfortable. These ranges vary from individual to individual; they also vary from country to country.
In the 1950s, Americans visiting Europe were often surprised to learn that central heating was rare in Britain. As temperatures dropped, Britons reacted by putting on a sweater and brewing a cup of tea, and waited far longer to turn on a space heater than American visitors thought reasonable.
In a passive solar house, daily temperature ranges can be wider than some people are used to. As long as thermostats aren't set to keep the interior space in a very narrow range, a passive solar house might be 60° F at dawn and 79° F at 2 p.m. A wide temperature range improves the performance of a passive solar house, since efficient storage of solar heat requires that the house have a low starting temperature in the morning. If homeowners can adapt to wider comfort ranges, their energy bills and environmental impact will be lower.
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Fresh Air: Not Too Much, Not Too Little
A tightly sealed home without mechanical ventilation can be smelly and humid. When air is stale, everyone reacts the same way: it's time to open a window. But if the outdoor temperature is 10° F, opening a window quickly makes occupants uncomfortable.
If a house has a properly designed and functioning mechanical ventilation system, the air should stay fresh with minimal occupant intervention.
Clearly, too little fresh air is a problem. But overventilation should also be avoided, since the operation of a ventilation system always carries an energy penalty. In winter, outdoor air must be heated, and in summer, outdoor air may have to be cooled and dehumidified. The solution is a mechanical ventilation system that brings in a small amount of ventilation air — just enough to prevent smells and humidity problems.
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STALE AIR MAKES US UNCOMFORTABLE
Dryer Is Better
When choosing between high and low indoor relative humidity, it's always safer to choose lower humidity levels. Far more problems are caused by humidifiers than dehumidifiers.
A well designed home should not need a humidifier. Very dry indoor air during the winter is usually a sign that the house has too many air leaks. When air leaks out of the house through ceiling cracks, it's replaced with very dry exterior air entering through cracks at the mudsill and basement rim joist.
Installing a humidifier in such a house can lead to disaster. If the indoor relative humidity is raised, moisture can condense on cold surfaces inside the walls or the attic, leading to mold and rot.
If air sealing work is performed in the attic and basement, the indoor relative humidity will rise — without increasing the risk of rot and mold.
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AVOIDING MOLD AND MILDEW
Infiltration and Exfiltration
Some older houses leak so much air that occupants are made uncomfortable in winter by cold drafts under doors, through windows, or even through electrical receptacles.
Air leaks in newer homes are often more subtle. Because modern exterior doors and windows include better weatherstripping, occupants may not notice drafts. But large volumes of indoor air may still be escaping into the attic through cracks in the ceiling, while outdoor air simultaneously enters the basement through cracks under the mudsill.
Improving the home's air barrer will plug these hidden air leaks, lowering heating and cooling costs. When a drafty home is sealed, the reduction in the home's air exchange rate leads to a rise in indoor relative humidity during the winter, improving occupant comfort.
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IMPROVING A HOME'S AIR BARRIER
Good Glazing Improves Comfort
In many homes, the windows are the most important factor affecting a home's cooling load — far more important than the home's insulation levels. A room with large windows facing west will be very hot on summer afternoons, especially if the windows have ordinary clear glazing.
If the HVAC(Heating, ventilation, and air conditioning). Collectively, the mechanical systems that heat, ventilate, and cool a building. installer properly anticipates this problem, the room can be served by a powerful air conditioner connected to high-capacity ductwork. Although this "solution" may keep occupants comfortable, they won't be happy with their electricity bills.
A green home will tackle the problem differently, using a combination of strategies:
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NO ONE ENJOYS COLD GLASS
Comfort is what feels right
Comfort is the most subjective quality of home building. Different people offer different judgments of the same room at the same time. Air temperature, mean radiant temperatureMean radiant temperature (MRT) is roughly the average temperature of all the objects or surfaces that a person "sees" inside a building, with the surface temperatures being weighted by their area. A surface or object's contribution to MRT is also based on its temperature in comparison to the person (temperature difference or differential) and the viewing angle between the person and the surface., relative humidity, and air movement all play a part, but ASHRAE bases its comfort standards on two things: temperature and humidity.
Moreover, people's comfort ranges vary during the course of a year. A comfortable thermostat setting during winter (65°F) might feel much too cold in August.
Because of comfort's subjective nature, ASHRAE’s comfort standards aim to keep about 80% of the population happy.
Controlling the indoor temperature isn’t enough to make a house pleasant.
It must be engineered for comfort with four basic strategies:
1. Good thermal envelope (including high-performance windows) to control radiant temperatures
2. Airtight envelope to minimize drafts
3. Air movement to increase comfort during cooling seasons
4. Ventilation to remove humidity and to encourage cooling convective currents during the summer
Tight houses need a mechanical lung
The HVAC(Heating, ventilation, and air conditioning). Collectively, the mechanical systems that heat, ventilate, and cool a building. system plays a crucial role in controlling temperature and humidity. Heating and air conditioning obviously affect the temperature, but it’s important not to overlook ventilation.
The first goal of ventilation is to control moisture and odors at their source with properly-sized exhaust fans in bathrooms and kitchens. A humidistat or timer rather than a switch ensure that fans run long enough to expel humid air.
The second goal of ventilation is to regulate the fresh air (measured in air changes per hour, or ACHACH stands for Air Changes per Hour. This is a metric of house air tightness. ACH is often expressed as ACH50, which is the air changes per hour when the house is depressurized to -50 pascals during a blower door test. The term ACHn or NACH refers to "natural" air changes per hour, meaning the rate of air leakage without blower door pressurization or depressurization. While many in the building science community detest this term and its use (because there is no such thing as "normal" or "natural" air leakage; that changes all the time with weather and other conditions), ACHn or NACH is used by many in the residential HVAC industry for their system sizing calculations.) in the house.
A mechanical ventilation system also exhausts humidity from people breathing and perspiring, but during the summer it can also bring outdoor humidity into the house. Energy-recovery ventilators transfer humidity between two air streams: the incoming fresh air stream and the stale exhaust air stream. Humidity moves from the more humid air stream to the dryer air stream.
Humidity is half of the comfort equation
The right mix of temperature and humidity is a health issue and a comfort issue.
Relative humidity (R.H.) is the amount of water vapor in the air as a percent of the total amount of moisture the air can hold at that temperature. When R.H. reaches 100%, condensation occurs. As temperature rises air can hold more moisture, as temperature falls the air can hold less moisture.
When warm, moist air contacts a cold surface, the air cools, and at this lower temperature the air cannot support as much water vapor so condensation occurs. If humidity levels are high enough, fabric, paper-faced drywall, and wood can all support mold growth.
Not only does humidity affect comfort, it affects mold and mite growth
As a rule, R.H. should be kept below 70% because that level can support mold, corrosion, and dust mites. But it’s important to consider where the R.H. is measured. The R.H. in the middle of a room will be different than the R.H. on the wall and window surface if there is a significant temperature difference between the two.
When it's cold outside, condensation has a chance
Because of the big temperature differences between inside and outside of a wall, it's easy for the inside surface of a wall to feel a little cold. The colder it gets, the lower the indoor R.H. must be to prevent the dreaded 70% R.H. on windows.
Green homes in cold areas boost their levels of insulation and control humidity with ventilation. Rigid foam wall sheathingMaterial, usually plywood or oriented strand board (OSB), but sometimes wooden boards, installed on the exterior of wall studs, rafters, or roof trusses; siding or roofing installed on the sheathing—sometimes over strapping to create a rainscreen. helps keep wall cavities warm, reducing the possibility that moisture will condense inside wall cavities.
When it's hot outside the situation is a little different
When hot outdoor air is cooled by an air conditioner, the R.H. goes up. Fortunately, an air conditioner's cooling coil acts as a dehumidifier. Nevertheless, a poorly designed air conditioning system with leaky ductwork can pull moisture into a house. In depressurized leaky houses, moisture can be sucked in through cracks in walls and floors. In green houses, however, air movement is more controlled and predictable.
In an air-conditioned home, mold can take hold on the back side of drywall if humid air gets inside the wall and condenses on the cool inside wall surface. Wall coverings, especially impermeable ones like vinylCommon term for polyvinyl chloride (PVC). In chemistry, vinyl refers to a carbon-and-hydrogen group (H2C=CH–) that attaches to another functional group, such as chlorine (vinyl chloride) or acetate (vinyl acetate). wallpaper, can trap condensation and create mold problems.
To avoid this problem in a hot humid climate, don't install air conditioning. If the home must be air conditioned, use the following strategies:
1. Limit the leaks by pressurizing the house slightly
2. Install an exterior vapor retarder*
3. Build air-tight
4. Dehumidify R.H. to 60% at 75°F
5. Avoid plastic vapor barriers and vinyl wallpaper if you air condition.
*Some types of exterior vapor retarders should never be used in a mixed climate
Air leaks usually occur where two dissimilar materials meet
The building envelopeExterior components of a house that provide protection from colder (and warmer) outdoor temperatures and precipitation; includes the house foundation, framed exterior walls, roof or ceiling, and insulation, and air sealing materials. plays a critical role in comfort. Drafts will leave people feeling cold in the winter regardless of the thermostat setting.
To limit drafts, a home requires an effective air barrier. Air barriers usually fail where two dissimilar materials meet: for example, between a concrete foundation and the mudsill, between a rough opening and a window frame, or between a subfloor and the bottom plate of wall. Other problem areas include interior kitchen soffits along exterior walls; walls behind bathtubs on exterior walls; cantilevered floors; and fireplace surrounds.
After the installation of air barrier materials, caulk, and strategically placed spray foam, but before the installation of gypsum wallboard, every house should be tested for air leakage with a blower door.
Preventing air movement in the walls is also important. While popular and relatively cheap, fiberglass insulation is the worst performing insulation choice because it leaves plenty of gaps for convective air currents within the wall assembly. In a home lacking an effective air barrier, warm air can contact cold surfaces inside a wall, leading to condensation. Spray foam and dense-packed cellulose insulationThermal insulation made from recycled newspaper or other wastepaper; often treated with borates for fire and insect protection. are more effective at reducing air infiltration than fiberglass batts.
Bad windows can literally give us a chill
Windows significantly affect occupant comfort. During the winter, the interior face of window glazingWhen referring to windows or doors, the transparent or translucent layer that transmits light. High-performance glazing may include multiple layers of glass or plastic, low-e coatings, and low-conductivity gas fill. is almost always the coldest surface in any room. Whenever the temperature of the widow glass is lower than human skin temperature, our body heat will radiate towards the windows, giving us a chill.
Older, single-pane windows cause discomfort year round, as they suck heat from occupants during winter and admit unwanted solar heat in summer. Moreover, they are often drafty. Double- and triple-glazed windows provide far superior U-factorMeasure of the heat conducted through a given product or material—the number of British thermal units (Btus) of heat that move through a square foot of the material in one hour for every 1 degree Fahrenheit difference in temperature across the material (Btu/ft2°F hr). U-factor is the inverse of R-value. ratings. (U-factor is a measure of the rate of non-solar heat flow through a window or skylight. An R-valueMeasure of resistance to heat flow; the higher the R-value, the lower the heat loss. The inverse of U-factor. is a measure of the resistance of a window to heat flow and is the reciprocal of a U-factor. Lower U-factors, or higher R-values, indicate reduced heat flow.)
Efficient windows with low U-factors are less susceptible to condensation, something of a litmus test of their comfort because condensation only occurs when air at the window is cooled to its dew point. Windows with a low U-factor also stay warmer during the winter, reducing the radiant cooling effect.
U-factor isn’t the only performance measure to use when selecting windows. Rather than taking a “one-size-fits all” approach when specifying the solar heat gain coefficient(SHGC) The fraction of solar gain admitted through a window, expressed as a number between 0 and 1. (SHGCSolar heat gain coefficient. The fraction of solar gain admitted through a window, expressed as a number between 0 and 1.) of windows, tune window performance by selecting different SHGCs depending on the orientation of each window. Use low SHGC values to reduce solar heat gain on west- and (in some climates) east-facing windows and high SHGC values take advantage of solar gain from south-facing windows to warm the house.
There's another way windows can help keep a house cool without resorting to air conditioning: placing operable windows low on the windward side of the house and higher on the leeward side encourages cross ventilation and encourages convective cooling.
Low-e coatings improve the comfort and efficiency of double- and triple-glazed windows by lowering a window's U-factor. Low-eLow-emissivity coating. Very thin metallic coating on glass or plastic window glazing that permits most of the sun’s short-wave (light) radiation to enter, while blocking up to 90% of the long-wave (heat) radiation. Low-e coatings boost a window’s R-value and reduce its U-factor. coatings reflect heat back into the house during cold weather and back to the outdoors during warm weather — increasing the insulating value of the window.
A low-e coating is a microscopically thin, virtually invisible, metal or metallic oxide coating deposited on a glazing surface. The coating may be applied to one or more of the glazing surfaces facing an air space in a multiple-pane window, or to a thin plastic film inserted between panes. ArgonInert (chemically stable) gas, which, because of its low thermal conductivity, is often used as gas fill between the panes of energy-efficient windows. or kryptonA colorless, odorless inert gas, often used with argon in fluorescent lighting and sometimes used as gas fill in high-performance glazing. gas is often added to the space between panes in low-e windows because they are better insulators than air.
- Don Mannes/Fine Homebuilding
- Fine Homebuilding 178
- Fine Homebuilding 114
- Daniel Morrison
- Dan Thornton/Fine Homebuilding 114
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